Thursday, March 15, 2018

The German Culture's influence on Gauss

Gauss was born a few years before Frederick the Great died (while Germany was still known as Prussia). Frederick the Great was a fervent nationalist who led several aggressive expansionist campaigns against neighboring Austria, Poland, and Silesia. The German people revered Frederick the Great (almost idolizing him). In fact, in much of the propaganda that Hitler and the Nazi party distributed during his campaign for power compared him to the next Frederick the Great. Based on this, it is very likely that Gauss held him in high esteem as well. Throughout his life, he was strongly patriotic and loyal to the crown.

Friedrich Zweite Alt.jpg

Later in life, as the Napoleonic Wars broke out across Europe, Gauss staunchly supported the German monarchy and condemned the revolution and condemned Napoleon as an insurgent. As a result of the Wars, Prussia became a superpower in Europe leading to an even greater upswing in national pride.

Portrait of Napoleon in his forties, in high-ranking white and dark blue military dress uniform. In the original image He stands amid rich 18th-century furniture laden with papers, and gazes at the viewer. His hair is Brutus style, cropped close but with a short fringe in front, and his right hand is tucked in his waistcoat.

This nationalistic attitude likely affected how Gauss approached his career - he was a very independent worker, which may have been sparked as an outgrowth of the national pride. In his life, he was very reluctant to work with others - especially non-Germans. He also took very few students, and all of his most famous students (Bernhard Riemann, Peter Gustav Lejeune Dirichlet, Moritz Cantor, August Ferdinand Möbius) were all German. One of Gauss's only foreign correspondents was Sophie Germain, a French mathematician. Gauss wholeheartedly supported Germain and recommended that she receive an honorary degree for her work in number theory. But, due to prejudice at the time, this request was never honored and she never received her degree and much of her work went unrecognized in her lifetime.

Image result for sophie germain


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Sunday, March 11, 2018

Gauss's Applied Mathematics -- Physics and Statistics

One of Gauss's most important accomplishments is in the development of Gauss's Theorem (also known as the Divergence Theorem), which he used to make several important developments in the physical theory of electromagnetism. Qualitatively, Gauss's Theorem links the flux of a vector field through some closed surface to the divergence of the field inside the surface.Quantitatively, Gauss showed that the following was true:
\color{white} \HUGE \iiint_V (\vec{\nabla} \cdot \vec{F}) dV = \iint_{S} (\vec{F} \cdot \vec{n}) dS 
Where V is any volume, F is any field, S is the surface enclosing V, and n is the vector normal to the surface. 

Image result for divergence theorem

An intuitive way to think about this is that F describes something that is flowing (e.g., a gas or a fluid). The divergence of F would then describe the expansion or compression of the gas or fluid. Gauss's Theorem says that the total expansion (or compression) of the gas with some volume V is equal to how much "stuff" is entering (or leaving) the surface S.

Probably the most important application of Gauss's Theorem is in the physical theory of electromagnetism. Gauss was able to show that the electric flux is equal to the charge enclosed by the volume divided by a constant (ε0). In other words,
\color{white} \HUGE \iint_S (\vec{E} \cdot \vec{n}) dS = \dfrac{Q_{\text{enclosed}}}{\epsilon _0}
Gauss did the same thing for the magnetic flux and found:
\color{white} \HUGE \iint_S (\vec{B} \cdot \vec{n}) dS = 0
Physically, this shows that the electric field points radially away from positive charges (radially into negative charges) such that the total divergence is Q/ε0
Image result for gauss law for electric field
For magnetism, Gauss showed that the magnetic field has no divergence. The magnetic field can circulate, but cannot do anything else. In other words, all field lines that enter the Gaussian surface must also leave the surface. 
Image result for gauss law for magnetic fields 

Gauss's Theorem provided the theoretical foundation for Gauss's laws of electricity and magnetism, which remain the backbone of electromagnetism to this day. 


Of equal importance was Gauss's development in probability theory of a way to handle random variables that each have unknown distributions. Today, this is known as a normal or Gaussian distribution. A fun way to visualize this is with a Galton board.

The Gaussian distribution is incredibly useful because of the central limit theorem, which says that the sum of independent random variables will always tend to a Gaussian distribution. This theorem makes the Gaussian distribution remarkably powerful and applicable, and it can be used to model useful data such as people's heights, blood pressure, IQ scores, and salaries. Because of their incredible applicability, Gaussian distributions are ubiquitous throughout all of branches of Applied Mathematics including physics, economics, and psychology.
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The German Culture's influence on Gauss

Gauss was born a few years before Frederick the Great died (while Germany was still known as Prussia). Frederick the Great was a fervent nat...

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